Method of forming trench MOS device and termination structure

ABSTRACT

A method for fabricating trench MOS devices and termination structure simultaneously is disclosed. The MOS devices can be Schottky diode, IGBT or DMOS depending on the semiconductor substrate prepared. The method comprises following steps: firstly, forming a plurality of first trenches for forming the trench MOS devices in an active region, and a second trench for forming the termination structure. Thereafter, a thermal oxidation process to form a gate oxide on all areas is performed. Then, the first trenches and the second trench are refilled with a first conductive material. An etching back is carried out to remove excess first conductive material so as to form spacer in the second trench and to fill the first trenches only. Next, the gate oxide layer is removed. For IGBT or DMOS device, an extra thermal oxidation and an etching step are required to form inter-conductive oxide layer whereas for Schottky diode, these two steps are skipped. Thereafter, a termination structure oxide layer is formed through deposition, lithographic process and etching. After backside unnecessary layers removal, a sputtering metal layers deposition, lithographic process and etching step are successively performed to form the first electrode with a desired ended location and the second electrode on both side of semiconductor substrate.

FIELD OF THE INVENTION

The present invention relates to a semiconductor process, specifically, to a novel termination structure for trench MOS devices so as to prevent leakage current.

BACKGROUND OF THE INVENTION

Doubled diffused metal-oxide-semiconductor field effect transistor (DMOSFET), insulated gate bipolar transistor (IGBT), and Schottky diode are important power devices and use extensively as output rectifiers in switching-mode power supplies and in other high-speed power switching applications. For example, the applications include motor drives, switching of communication device, industry automation and electronic automation. The power devices are usually required carrying large forward current, high reverse-biased blocking voltage, such as above 30 volt, and minimizing the reverse-biased leakage current. There are several reports that trench DMOS, trench IGBT and trench Schottky diode are superior to those of with planar structure.

For power transistors are concerned, apart from the device in the active region for carrying large current, there is still required a termination structure design in the periphery of the active region usually at an end of a die so as to prevent voltage breakdown phenomena from premature. Conventional termination structures include local oxidation of silicon (LOCOS), field plate, guard ring, or the combination thereof. The LOCOS is generally known to have bird beak characteristic. In the bird beak, electric field crowding phenomena is readily to occur, which is due to high impact ionization rate. As a result, leakage current is increased and electrical properties of the active region are deteriorated.

For example, please refer to FIG. 1, a semiconductor substrate with trench MOS structure for Schottky diodes, and a trench termination structure formed therein. The substrate is a heavily doped n+ substrate 10 and an epitaxial layer 20 formed thereon. A plurality of trench MOS 15 formed in the epitaxial layer 20. The trench MOS devices including epitaxial layer 20/gate oxide layer 25/polysilicon layer 30 are formed in the active region 5. The boundary of the active region 5 to the edge of the die is a LOCOS region of about 6000 Å in thick formed by conventional method.

For the purpose of lessening the electric field crowding issue, a p+-doping region 50 beneath LOCOS region is formed through ion implantation. The p+-doping region 50 is as a guard ring for reverse-biased blocking voltage enhancement. The anode (a metal layer) 55 is formed on the active region 5 and extends over p+ doping region 50 of LOCOS region. The object is to make the bending region of the depletion boundary far away from the active region 5. Although guard ring 50 can alleviate the electrical field crowding and relax the bending magnitude occurred near the active region, the adjacent region between p+ region 50 and beneath the bottom of the trench MOS device, as arrow indicated denoted by 60, is not a smooth curve. It will increase the leakage current and decrease the reverse-biased blocking capability. A similar situation occurred for field plate combines with guard ring. Furthermore, aforementioned prior art demanded more photo masks (at least four) to fabricate, and the processes are rather complicated. Still high cost for forming such structure is another inferior.

As forgoing several conventional termination structures can not solve the problems thoroughly. An object of the present invention thus proposes a novel termination structure. The new termination structure made the bending region of the depletion region far away from the active region, and depletion boundary is flatter than forgoing prior art. The manufacturing method provided by the present invention is even simpler than those prior arts. Since the termination structure and trench are formed simultaneously, it requires only three photo masks, low complicated processes and low cost.

SUMMARY OF THE INVENTION

The present invention discloses a method for fabricating trench MOS devices and termination structure simultaneously. The MOS devices can be Schottky diode, DMOS or IGBT, depending on the semiconductor substrate prepared, and are, respectively, illustrated in the first preferred embodiment, second preferred embodiment and third preferred embodiment. The method of the first preferred embodiment comprises following steps: firstly, forming a plurality of first trenches for forming the trench MOS devices in an active region, and a second trench for forming the termination structure. Thereafter, a thermal oxidation process proceeds to form a gate oxide on all areas. Then, the first trenches and the second trench are refilled with a first conductive material. An etching back process is carried out to remove excess first conductive material so as to form spacer on the second trench and to fill the first trenches only. Next, the gate oxide layer is removed. Thereafter, a termination structure oxide layer is formed through deposition, lithographic and etching processes. After backside unnecessary layers removal, a sputtering metal layers deposition, lithographic process and etching step are successively performed to form first electrode and second electrode on both side of semiconductor substrate.

For the second and third preferred embodiment, an extra thermal oxidation and an etching step are required to form inter-conductive oxide layer before termination structure oxide layer is deposited. So the first conductive layer is isolated from the second conductive layer by the inter-conductive oxide layer.

BRIEF DESCRIPTION OF THE DRAWINGS

The foregoing aspects and many of the attendant advantages of this invention will become more readily appreciated as the same becomes better understood by reference to the following detailed description, when taken in conjunction with the accompanying drawings, wherein:

FIG. 1 is a conventional trench Schottky diode devices and LOCOS plus guard ring as a termination structure.

FIG. 2 is a cross-sectional view of forming first trenches and second trench in a semiconductor substrate in accordance with the present invention.

FIG. 3 is a cross-sectional view of refilling the first trenches and the second trench with a first conductive material in accordance with the present invention.

FIG. 4 is a cross-sectional view of defining termination structure oxide layer to expose active region and spacer in accordance with the present invention.

FIG. 5A is a cross-sectional view of forming anode electrode and cathode electrode on both side of the semiconductor substrate so that Schottky diode and the termination structure are finished in accordance with the present invention.

FIG. 5B shows simulation results of equipotential lines and lines of electric force by using Schottky diode and the termination structure of the present invention.

FIG. 5C shows simulation results of leakage current of trench Schottky diode with and without the termination structure of the present invention.

FIG. 6 is a cross-sectional view of semiconductor substrate prepared for DMOS device and termination structure in accordance with the present invention.

FIG. 7 is a cross-sectional view of etching back first conductive layer and then performing a high temperature thermal oxidation process to form inter-conductive oxide layer in accordance with the present invention.

FIG. 8 is a cross-sectional view of defining termination structure oxide layer to expose active region and spacer in accordance with the present invention.

FIG. 9 is a cross-sectional view of forming source electrode and drain electrode on both side of the semiconductor substrate so that DMOS device and the termination structure are finished in accordance with the present invention.

FIG. 10 is a cross-sectional view of semiconductor substrate prepared for IGBT and termination structure in accordance with the present invention.

FIG. 11 is a cross-sectional view of defining termination structure oxide layer to expose active region and spacer in accordance with the present invention.

FIG. 12 is a cross-sectional view of forming emitter electrode and collector electrode on both side of the semiconductor substrate so that IGBT and the termination structure are finished in accordance with the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

As depicted in the forgoing background of the invention, the conventional termination structure including local oxidation, electric field plate, guard ring, or the combination thereof, all of them do not solve completely the electric field crowding issues. The field crowding may still occur at different positions, depending on the design difference. The present invention proposes a novel trench termination structure and a method to make them. The novel trench termination structure is to overcome problems of electric field crowding issues. The newly trench termination provides a flat depletion boundary, and the bending region-thereof is far away from the active region while encountered a reverse-bias voltage. Consequently, the novel termination structure can prevent breakdown phenomena from being occurred prematurely.

Moreover, the newly termination structure can be applied to any power transistors such as Schottky rectifier, DMOS, IGBT etc. The most important fact is the trench MOS devices can be formed with the trench termination structure simultaneously.

Several exemplified embodiments will be successively illustrated.

The first preferred embodiment is to illustrate the method of forming trench termination structure and the Schottky diode simultaneously.

Please refer to FIG. 2, a cross-sectional view shows a semiconductor substrate 100 comprised a first layer 100A having a first kind of conductive impurity doped (for example type n) and a base substrate 100B having a first kind of conductive impurity heavily doped (for example n+). First layer 100A is formed epitaxially on the base substrate 100B for forming Schottky contact and the base substrate is for forming ohmic contact while metal layers are formed thereon.

An oxide layer 101 is then formed on the first substrate 100A by CVD to about 2000 Å-10000 Å. Next, a photoresist (not shown) is coated on the oxide layer 101 to define a plurality of first trenches 110 and a second trench 120. Each of the first trenches 110 is about 0.2-2.0 μm in width from cross-sectional view formed in the active region. The second trench 120 is spaced by a mesa 115 to the first trench 110 and formed from the boundary of the active region to an end of a semiconductor substrate 100 (or a die). The second trench 120 is to make depletion boundary flat and prevent electric field crowding.

Referring to FIG. 3, after oxide layer 101 removal, a high temperature oxidation process to form gate oxide layer 125 is performed. The gate oxide layer 125 with a thickness between about 150 Å to 3000 Å is formed on the sidewalls 110A, 120A, bottoms 110B, 120B of the first and second trench 110, 120, and the mesa surface 115A. Alternatively, the gate oxide layer 125 can be formed by high temperature deposition to form HTO (high temperature oxide deposition) layer.

Subsequently, a first conductive layer 140 is formed by CVD on the gate oxide 125 and refilled the first trench 110 and the second trench 120, and at least with a height higher than the mesa 115. The first conductive layer 140 is also formed on the backside of the semiconductor substrate 100E due to the CVD process. The first conductive layer is material selected from the group consisting of metal, polysilicon and amorphous silicon. Preferably, the first conductive layer 140 is about 0.5 to 3.0 μm. For preventing inner portion of first trench from forming voids therein, the polysilicon layer formed by LPCVD (low pressure CVD) which has good step coverage is preferred as the material of the first layer 140. However if the aspect ratio of first trench 110 over 5, amorphous silicon by PECVD would be preferred. The amorphous silicon has better gap filled characteristic than polysilicon. Surely, to make it with conductive properties, an amorphous silicon recrystallized process is needed.

Please refer to FIG. 4, an anisotropic etching is done to remove the excess first conductive layer 140 above the mesa surface 115A using the gate oxide layer 125 on the mesa 115 as an etching stop layer. After this process, a spacer 122 having a width (along cross-sectional view) about the same as the height of the second trench is formed on the sidewall 125A of the second trench 120.

Thereafter, a dielectric layer 150 for termination structure is formed. The dielectric layer is a TEOS layer either LPTEOS or PETEOS or O₃-TEOS or HTO layer. The dielectric layer 150 is between about 0.2-1.0 μm.

Next, a photo resist pattern 155 is coated on the dielectric layer 150 so as to define ranges of Schottky contacts. And then a dry etching using photoresist pattern 155 as a mask is carried out to expose mesa surface 115A and first conductive layer 140 of the first trench 110.

Turning to FIG. 5 after stripping the photoresist pattern 155, a backside unwanted layer removal is implemented to expose surface of the base substrate 100B. The unwanted layers are those layers formed on the backside of semiconductor substrate due to thermal oxidation process or CVD process for fabricating devices in the active region, including dielectric layer 150, first conductive layer 140, and gate oxide layer 125.

Thereafter, a sputtering process is performed to deposit second conductive layer so as to form Schottky contact regions 115 between second conductive layer and the first substrate 100A and to form cathode 160, which is an ohmic contact between second conductive layer and the second substrate 100B. Finally, a photoresist pattern 165 is formed on the second conductive layer to define anode electrode 160A. In a preferred embodiment, the anode 160A is formed from active region extending to the second trench 120 and at least to a region away from the active region by 2.0 μm. So the bending region of the depletion region is able to be far away from the active region.

FIG. 5B shows one of the electric properties of the trench MOS termination structure (shown in FIG. 5A). To simulate the reverse bias, for example, Schottky diode is exerted by a reverse bias. Hence, the cathode 160 has, for example, 100 Volt and anode 183 has 0 Volt. The numeral 180 denotes equipotential lines. In the figure, the voltages burdened by the equipotential lines from bottom to up are gradually decreased. The lines perpendicular to the equipotential lines 180 represent lines of electrical force. As shown in the figure, leakage current only generates in the active region and almost none in the depletion region under termination region. Moreover, the boundary of depletion region, denoted by label 180A, gives flat characteristic, and thus the voltage breakdown premature would not occur. It gives only a little bit of leakage current.

FIG. 5C shows a comparison for reversed current curves of the trench MOS structure without termination structure 195 and with the termination structure 190 in accordance with the present invention. The termination structure merely increases reversed current by 8.8%. By contrast to 12.8% occurs in the conventional termination structure, the LOCOS combines with guard ring structure. The present invention gives significant improvement. In addition, it requires at least 4 photo masks by conventional manufacture processes compared to three masks only in the present invention (e.g., forming trench (1^(st)), contact definition (2^(nd)), and the second conductive layer etching to form anode (3^(rd))). The present invention gives a simpler process.

The second preferred embodiment using the termination structure according to the present invention is to form trench DMOS structure and termination structure.

Referring to FIG. 6, for DMOS structure, the semiconductor substrate prepared is different from the case of forming Schottky diode but processes are quite similar. To forming DMOS and termination structure simultaneously, firstly, a semiconductor substrate 200 from the top to the bottom comprises a first layer 200A, a second layer 200B and a base substrate 200C. The first layer 200A and the second layer are formed on the base substrate 200C by epitaxial processes.

The first layer 200A having a p-type conductive doped impurities as a base layer and then a doping layer 203 with p-type conductive heavily doped impurities on the top portion of the first layer 200A. The second layer 200B is with n-type conductive doped impurities, and the third layer 200C with n-type conductive heavily doped impurities. Furthermore, a plurality of n+ regions are formed in the upper portion of the first layer 200A to cut p+ layer 203 to be as many n+ regions 204 and p+ region 204 by ion implantation, as is shown in FIG. 6. The thickness of the first and second layer 200A and 200B are 0.5 μm-5.0 μm and 3 μm-30 μm, respectively.

Thereafter, please refer to FIG. 7, as forging method described in the first preferred embodiment, a plurality of the first trenches 210 and the second trench 220 having a mesa 215 in between are formed firstly. The first trenches 210 are formed in the active region, through n+ regions 204, and the second trench 220 is formed in the region from the boundary of the active region to an end of the semiconductor substrate 200 (or a die).

Next, a high temperature oxidation process is performed to form a gate oxide layer 225 with a thickness of between about 150 Å to 3000 Å. Then, a conductive layer 240 selected from first polysilicon or amorphous silicon is refilled to the first trenches 210 and the second trench 220 and over mesa 215. An etching back step is then carried out to remove excess conductive layer 240 using gate oxide layer 225 on the surface of mesa 215A as a stopping layer. The gate oxide layer 225 removal above mesa is then followed using the n+ region 204 and the p+ region 203 as a stopping layer.

Subsequently, another thermal oxidation process is performed to form an inter-conductive oxide layer 245 by oxidizing a portion of the first conductive layer 240. Since the grain boundaries of the polysilicon can provide oxygen fast diffusion paths, the oxide layer formed by the polysilicon or amorphous silicon in the first trenches 210 and the second trench 220 are much thicker than that on the semiconductor substrate, the mesa surface 215A.

Referring to FIG. 8 an etching back step is performed to remove thermal oxide layer 245 above surface of the first layer 200A, the n+ region 204 and p+ region 203. Worth to note, there is still a thermal oxide layer 245 on the spacer 240 of the second trench 220 and on the top surface of first conductive layer 240 after this step to provide isolation function. A TEOS oxide layer 250 is then formed on all areas. A photoresist pattern is then formed on TEOS oxide layer 250 of the first layer 200A to define source contact regions.

Referring to FIG. 9, before performing a sputtering process, the unwanted layers formed on the backside of semiconductor substrate (or say base substrate 200C) are removed firstly. The unwanted layers includes TEOS oxide layer 250, inter-conductive oxide layer 245, first conductive layer 240 and gate oxide layer 225 on the surface of base substrate 200C, which are formed simultaneously while making the devices in the active region.

Subsequently, a metal layer 260 deposition by sputtering is performed to form source contact on the first layer 200A and drain contact on the base substrate 200C i.e. the backside of the semiconductor substrate. As before, the metal layer 260 formed on the active region is still required to extend to the termination structure 220 by a distance at least about 2.0 μm so as to distant from the active region. To do this, a lithographic and an etching process are successively carried out as before.

The third preferred embodiment using the termination structure according to the present invention is to form trench IGBT structure and termination structure simultaneously.

Referring to FIG. 10, for the trench MOS to be as the IGBT structure, the semiconductor substrate prepared is different from the case of forming Schottky diode but very similar to the semiconductor substrate using for trench DMOS device. In addition, the process is almost the same as the processes of fabricating trench DMOS. To forming IGBT and termination structure simultaneously, firstly, a semiconductor substrate 300 prepared from the top to the bottom comprises a first layer 300A, a second layer 300B, a third layer 300C and a base substrate 300D. The first layer 300A, the second layer 300B, and third layers 300C, are formed on the base substrate 300D by epitaxial processes.

The first layer 300A, 300B and 300C having doping type, and doping concentration similar to the semiconductor substrate shown in FIG. 6. For example, first layer 300A is p-type base layer having upper portion n+ regions 304 and p+ regions 303 in the upper portion of the p-base layer 302. The second layer 300B is a n-doping layer as a drift region and third layer 300C is a n+ layer 300B as a buffer layer. The base substrate 300D is, however, a p-type conductive impurities heavily doped region. The thickness of the first and the second layer 300A and 300B are 0.5 μm-10.0 μm and 3 μm-100 μm, respectively.

Turning to FIG. 11, a plurality of the first trenches 310 are formed through the n+-doped region 304. The bottom of the first trenches 310 comes down to below the layer of the p-type-doped layer 302. Furthermore, the second trench 320 and first trench individual, each is spaced by a mesa 315 having 0.2 to 4.0 μm. The second trench 320 is formed at the boundary of the active region and is extended to an edge of the semiconductor substrate.

After an thermal oxidation process to form a gate oxide layer with a thickness of between 150 Å to 3000 Å, a refilled process with the first conductive material 340 such as polysilicon or amorphous silicon layer is deposited on the first trenches 310 and the second trench 320. An etch back process is then performed using gate oxide layer 325 on the surface of the mesa 315 as a stopping layer so that only the first trenches 310 and spacer in the second trench have the first conductive material 340.

As the second embodiment depicted before, gate oxide layer 325 on the surface of the first layer is then removed and then another thermal oxidation process is carried out to form inter-conductive oxide layer 345 for the conductive layer 340 and the metal layer (formed later) isolation. Thereafter, the thermal oxide 345 above mesa surface 315A is removed but a portion of the thermal oxide layer, which is on the first conductive layer in the first trenches 310 and the second trench 320 are remaining as an inter-conductive oxide layer.

Still referring to FIG. 11, a TEOS dielectric layer 350 deposition on all areas and photoresist pattern coating are followed successively as before. Thereafter, an etching process is implemented to expose the n+-doped region 204 and the p+-doped region.

FIG. 12 shows backside unwanted layers on base substrate are removed before metal sputtering. After the second conductive layer, generally, a metal layer is formed on a surface of base substrate 300D to form collector electrode. After successively lithographic and etching process, the emitter electrode is formed on the surface of 300A, which contacts the p+ region 303 and n+ region 304. One end of emitter electrode is located at a distance away from active region.

The benefits of this invention are:

(1) The depletion boundary is flat and the bending region of depletion boundary is far away from active region. Both the properties are able to prevent voltage breakdown phenomena from occurring prematurely.

(2) The leakage current generated by the invention termination structure during reversed-biased is small than that of conventional LOCOS plus guard ring termination structures (8.8% vs. 12.8%).

(3) The method for fabricating the trench MOS device with termination structure is simpler than that of conventional methods. The invention termination structure requires less photo masks.

As is understood by a person skilled in the art, the foregoing preferred embodiment of the present o invention is an illustration of the present invention rather than limiting thereon. It is intended to cover various modifications and similar arrangements included within the spirit and scope of the appended claims, the scope of which should be accorded the broadest interpretation so as to encompass all such modifications and similar structure. 

What is claimed is:
 1. A method of fabricating trench MOS devices and termination structure simultaneously, said method comprising the steps of: providing a semiconductor substrate; forming a plurality of first trenches for forming said trench MOS devices in an active region of a semiconductor substrate, and a second trench for forming said termination structure from a boundary of said active region to a margin of said semiconductor substrate, said second trench and said first trench spaced by a mesa; performing a thermal oxidation process so as to form a gate oxide on all areas of said semiconductor substrate; refilling said plurality of first trenches and said second trench with a first conductive material; performing an etching back process using a surface of said semiconductor substrate of said mesa as a stopping layer, and forming a spacer on a sidewall of said second trench; removing said gate oxide layer using said surface of said semiconductor substrate of said mesa as a stopping layer; forming a termination structure oxide layer on all areas of said semiconductor substrate; forming a photoresist pattern on said termination structure oxide layer to define an insulating region and to expose a region from said active region to said spacer; etching away said exposed region using said photoresist pattern as a mask; stripping said photoresist pattern; removing backside unnecessary layers of said semiconductor substrate so as to expose said semiconductor substrate; forming a second conductive material on all areas of said semiconductor substrate; forming a photoresist pattern on said second conductive material so as to define an electrode; and etching away exposed portion of said second conductive material so that said electrode is formed.
 2. The method of claim 1, wherein said semiconductor substrate comprises a first layer and a base substrate, said first layer having a first kind of conductive impurities lightly doped and said base substrate having a first kind of conductive impurities heavily doped, still said first trenches and said second trench being formed in said first layer.
 3. The method of claim 1, wherein said mesa having a width of between about 0.2-4.0 μm viewing along said active region to said second trench.
 4. The method of claim 1, wherein said step of forming a plurality of first trenches and a second trench comprising the steps of: forming an oxide layer on said semiconductor substrate; forming a photoresist pattern on said oxide layer to define said plurality of first trenches and said second trench; performing an anisotropic etching to transfer said photoresist pattern to said oxide layer; removing said photoresist pattern; performing an anisotropic etching to etching away said semiconductor substrate using said oxide layer as a hard mask; and removing said oxide layer.
 5. The method of claim 1, wherein said first trenches and said second trench are between about 0.4-10 μm in depth.
 6. The method of claim 1, wherein said gate oxide layer is between about 150-3000 Å.
 7. The method of claim 1, wherein said first conductive material is a material selected from the group consisting of metal, polysilicon and amorphous silicon.
 8. The method of claim 1, wherein said termination structure oxide layer is selected from the group consisting of HTO, LPTEOS, PETEOS and O₃-TEOS.
 9. The method of claim 1, wherein said backside unnecessary layers comprising said gate oxide layer, said first conductive material, and said termination structure oxide layer on backside of said semiconductor substrate.
 10. The method of claim 1, wherein said step of forming photoresist pattern to define an electrode is to define an anode electrode.
 11. The method of claim 2, wherein said step of forming a second conductive material on all areas is to form anode on said first layer and a cathode on said backside of said semiconductor substrate.
 12. The method of claim 10, wherein said anode electrode is formed to contact said active region, and said spacer, and is extended to form on a portion of said etched termination structure oxide layer so that bending region of a depletion is away from said active region at least 2.0 μm.
 13. A method of fabricating trench MOS devices and termination structure simultaneously, said method comprising the steps of: providing a semiconductor substrate; forming a plurality of first trenches for forming said trench MOS devices in an active region of a semiconductor substrate, and a second trench for forming said termination structure from a boundary of said active region to a margin of said semiconductor substrate, said second trench and said first trench spaced by a mesa; performing a thermal oxidation process so as to form a gate oxide on all areas of said semiconductor substrate; forming a first conductive layer to refill said plurality of first trenches and said second trench with a first conductive material; performing an etching back process using a surface of said semiconductor substrate of said mesa as a stopping layer, and forming a spacer on a sidewall of said second trench; removing said gate oxide layer using said surface of said semiconductor substrate of said mesa as a stopping layer; performing a thermal oxidation process so as to form inter-conductive oxide layer by consuming a portion of on said semiconductor substrate and a portion of said first conductive layer; removing said inter-conductive oxide layer using said surface of said semiconductor substrate of said mesa as a stopping layer; forming a termination structure oxide layer on all areas of said semiconductor substrate; forming a photoresist pattern on said termination structure oxide layer to define an insulating region and to expose a region from said active region to said spacer; etching away said exposed region using said photoresist pattern as a mask; stripping said photoresist pattern; removing backside unnecessary layers of said semiconductor substrate so as to expose said semiconductor substrate; forming a second conductive material on all areas of said semiconductor substrate so as to form a first electrode and second electrode on upper side and back side surfaces, respectively; forming a photoresist pattern on said second conductive material so as to define a position of said first electrode; and etching away exposed portion of said second conductive material so that said electrode is formed.
 14. The method of claim 12, wherein said trench MOS devices are DMOS transistors formed in said semiconductor substrate, said semiconductor substrate comprising from top to bottom layer having a first layer, a second layer, a third layer and a base substrate, said first layer having p-type conductive impurities heavily doped, said second layer having p-type conductive impurities lightly doped, said third layer having n-type conductive impurities lightly doped, said base substrate having n-type conductive impurities heavily doped, still a plurality of n-type conductive impurities heavily doped region formed in said first layer and in an upper portion of said second layer.
 15. The method of claim 12, wherein said trench MOS devices are IGBTs formed in said semiconductor substrate, said semiconductor substrate comprising from top to bottom layer having a first layer, a second layer, a third layer, a forth layer and a base substrate, said first layer having p-type conductive impurities heavily doped, said second layer having p-type conductive impurities lightly doped, said third layer having n-type conductive impurities lightly doped, said forth layer having n-type conductive impurities heavily doped, said base substrate having p-type conductive impurities heavily doped till a plurality of n-type conductive impurities heavily doped region formed in said first layer and in an upper portion of said second layer.
 16. The method of claim 12, wherein said first trenches and said second trench are between about 0.4-10 μm in depth and are formed in said first layer, said second layer and an upper portion of said third layer.
 17. The method of claim 12, wherein said mesa having a width of between about 0.4-10 μm, viewing along said active region to said second trench.
 18. The method of claim 12, wherein said step of forming a plurality of first trenches and a second trench comprising the steps of: forming an oxide layer on said semiconductor substrate; forming a photoresist pattern on said oxide layer to define said plurality of first trenches and said second trench; performing an anisotropic etching to transfer said photoresist pattern to said oxide layer; removing said photoresist pattern; performing an anisotropic etching to etching away said semiconductor substrate using said oxide layer as a hard mask; and removing said oxide layer.
 19. The method of claim 12, wherein said gate oxide layer is between about 150 Å-3000 Å.
 20. The method of claim 12, wherein said first conductive material is a material selected from the group consisting of polysilicon and amorphous silicon.
 21. The method of claim 12, wherein said termination structure oxide layer is selected from the group consisting of LPTEOS, PETEOS and O₃-TEOS.
 22. The method of claim 12, wherein said backside unnecessary layers comprising said gate oxide layer, said first conductive material, said inter-conductive oxide layer and said termination structure oxide layer on backside of said semiconductor substrate.
 23. The method of claim 13, wherein said step of forming photoresist pattern to define a first electrode is to define a source electrode.
 24. The method of claim 14, wherein said step of forming photoresist pattern to define an electrode is to define an emitter electrode.
 25. The method of claim 12, wherein said first electrode is formed to contact said active region, and said spacer, and is extended to form on a portion of said etched termination structure oxide layer so that a bending region of a depletion region away from said active region at least 2 μm. 